JPH07154270A - Error correction circuit - Google Patents

Abstract

PURPOSE:To improve the error correction capability by always setting data for a data missing period to '1' and applying error correction to the setting data again when error correction cannot be made due to missing of data in the case of reading and decoding data recorded on an information recording medium. CONSTITUTION:When at least part of data read from an information recording medium is missing, a data missing period detection section 4 detects it. When a data missing period is detected by the data missing period detection section 4, a replacement data generating section (272-bit missing flag memory section) 5 generates replacement data obtained by setting '1' or '0' to the missing data. Simultaneously after the data for the data missing period among data read from an information recording medium are replaced with data obtained by the replacement data generating section 5, an error correction section 8 decodes the corrected data with a preset error correction system to generate corrected data.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an error correction circuit for correcting an error in data recorded on an information recording medium, and more particularly to a write-once type information recording medium using an MFM-RZ encoding system (for example, optical card etc.). ) Relates to an error correction circuit for performing error correction on data recorded in (1).

SUMMARY OF THE INVENTION In the present invention, when data recorded on an information recording medium is read and decoded and error correction cannot be performed due to data loss, all data during the data loss period is "1". Is set again and error correction is performed again, and the error correction capability is greatly improved when there is a large amount of "1" data during the data loss period.

[0003]

2. Description of the Related Art As an encoding method for recording and reproducing data on a write-once type information recording medium such as an optical card,
Conventionally, NRZ encoding method, MFM encoding method,
Methods such as the MFM-RZ encoding method are known.

Then, these NRZ encoding methods, M
When the data stored in the information recording medium is read by each method such as the FM encoding method and the MFM-RZ encoding method, this data is input to the error correction circuit to correct the erroneous portion, and the syndrome is "0. If it is ", the error correction has succeeded and accurate data can be obtained, but if the syndrome is not" 0 ", the error correction has failed.

In this case, the NRZ encoding method is shown in FIG.
When the bit to be recorded is "1" as shown in (a), a current is passed in the positive direction as shown in FIG. 4 (b), and when the bit to be recorded is "0" in the opposite direction. The recording density is improved by passing a current and recording data while eliminating the period when the current becomes zero.

The MFM encoding method is shown in FIG.
When the bit to be recorded is “1” as shown in,
When magnetization reversal is performed and the bit to be recorded is “0” and there is only one bit, magnetization reversal is not performed and the bit to be recorded is “0” and when two or more bits are consecutive. By reversing the magnetization, the recording density is improved and the self-synchronous clock signal can be reproduced.

The MFM-RZ encoding method is shown in FIG.
As shown in (d), when a bit obtained by the MFM encoding method rises and when the bit falls, data is recorded by passing a current of a predetermined width. Therefore, when reading data, the self-synchronization clock In addition to facilitating signal reproduction and data read timing reproduction, when reading data at the center of the data period, if there is a rising edge at the center of the data period, it is determined as “1” and the edge If there is no rising, it is judged as "0".

[0008]

By the way, in such an error correction circuit, when the information recording medium is scratched or the like, the scratching causes the recording medium to be scraped and the edge cannot be detected. As shown in (e), since data is continuously lost in this portion, the error correction circuit cannot correct the data in this portion.

Therefore, in such an error correction circuit, when data is lost, generally all the data in the data loss period is set to "0" to perform error correction so that the data cannot be decoded. .

However, in this way, in the method of making all the lost data "0", if the original data is "0", the data can be decoded without error, but the original data is When the value is "1", the error correction may not be possible.

That is, when the information recording medium is scratched and the data is lost, the error rate can be reduced when the original data is "0", but when the original data is "1", Since the error rate becomes high, there is a problem that the data error rate depends on the data content.

In view of the above-mentioned circumstances, the present invention can prevent the error rate at the time of decoding from decreasing due to the contents of the original data even if the information recording medium is damaged and the data is continuously lost. It is therefore an object of the present invention to provide an error correction circuit that can significantly improve the error correction capability.

[0013]

To achieve the above object, the present invention provides an error correction circuit for decoding data read from an information recording medium by a preset error correction method. When at least a part of the data read from the information recording medium is lost, the data loss period detection unit for detecting this and the data loss period detection unit detect the loss of data. During the period, the alternative data generation unit that generates the alternative data in which all bits are “1” or “0”, and the data read during the data loss period of the data read from the information recording medium are replaced by the alternative data generation unit. An error correction unit that switches to data obtained by the data generation unit and then decodes by a preset error correction method to generate corrected data. That.

According to a second aspect of the present invention, the data read from the information recording medium is decoded by a preset error correction method to generate corrected data, and when the error correction processing fails. Among the data read from the information recording medium, the data during the data loss period is switched to the data obtained by the alternative data generation unit, and then decoded by a preset error correction method and corrected. And an error correction unit for generating the data of 1.

[0015]

In the above structure, according to claim 1, when at least a part of the data read from the information recording medium is lost, this is detected by the data loss period detection unit, and the data loss period is detected. While the data loss is detected by the detection unit, the replacement data generation unit generates replacement data in which all bits are “1” or “0”, and the error correction unit outputs the replacement data from the information recording medium. Of the read data, the data in the data loss period is switched to the data obtained by the alternative data generation unit, and then the data is decoded by a preset error correction method to generate corrected data. .

According to a second aspect of the present invention, the data read from the information recording medium by the error correction unit is decoded by a preset error correction method to generate corrected data, and this error correction processing is performed. When the data fails, of the data read from the information recording medium, the data during the data loss period is switched to the data obtained by the alternative data generation unit, and then decoded by a preset error correction method. Then, corrected data is generated.

[0017]

FIG. 1 is a block diagram showing an embodiment of an error correction circuit according to the present invention. This embodiment shows an error caused by the MFM-RZ encoding method and a (272,190) shortened difference set cyclic code. The error correction is performed using a correction method.

The error correction circuit 1 shown in this figure includes a data reading section 2, a timing reproducing section 3, a data erasure period detecting section 4, a 272 bit erasure flag memory section 5, and 272.
Bit data memory unit 6, control unit 7, and error correction unit 8
, Syndrome check unit 9, and changeover switch unit 10
And the MFM-RZ encoding method is used as an encoding method, and the error correction code (272, 19
0) With an optical card or the like using a shortened difference set cyclic code, already recorded data is read by a decoding method for the MFM-RZ encoding method, and if there is no data loss for this data, (272, 190) ) Data is decoded by performing error correction by an error correction method using a shortened difference set cyclic code, and when the data is lost, data in which all the lost portions in the data are set to “0” or loss in the data The data obtained by setting all of the above portions to “1” is used, and the data is decoded by performing error correction on these data by the error correction method using the (272,190) shortened difference set cyclic code.

The data reading unit 2 reads the data when reproducing the data recorded on the optical card or the like using the MFM-RZ encoding method and using the (272,190) shortened difference set cyclic code. This is supplied to the timing reproduction unit 3, the data loss period detection unit 4, and the 272 bit data memory unit 6.

The timing reproducing section 3 takes in the data output from the data reading section 2, detects the rising and falling edges of the bit, and judges "1" / "0" of the data based on the detection result. To generate a timing signal necessary for the
The 272-bit lost flag memory unit 5 is supplied.

Further, the data loss period detecting section 4 takes in the data output from the data reading section 2, detects the presence / absence of a rising or falling edge of the bit, and whether the data is lost based on the detection result. It is determined whether the bit is neither rising nor falling, and it is determined that the information recording medium is scratched and data is lost, and the determination result is supplied to the 272 bit loss flag memory unit 5.

The 272-bit erasure flag memory unit 5 fetches the determination result output from the data erasure period detection unit 4 based on the timing signal output from the timing reproduction unit 3, and this determination result is the data erasure period. When it is present, a flag indicating that it is lost data is set to "1" for each bit in the lost period, "0" is set to bits other than the lost period, and these are supplied to the control unit 7. .

Further, the 272 bit data memory unit 6 is
The data output from the data reading unit 2 is read bit by bit based on the timing signal output from the timing reproduction unit 3 and stored for 272 bits, and the stored 272 bit data is stored in the control unit 7. Supply.

The control unit 7 takes in the data output from the 272-bit data memory unit 6 and temporarily stores the data, supplies the data to the error correction unit 8, and then outputs the syndrome check result output from the syndrome check unit 9. Is 0, it is determined that the error correction of the output data has succeeded, and the data processing for one block code (272 bits) is completed. On the other hand, if the value of the syndrome check result output from the syndrome check unit 9 is not "0", it is determined that the error correction has failed,
The bit in the data loss period is obtained by ORing the temporarily stored data and the data output from the 272 bit loss flag memory unit 5 (data in which only the data loss period bit is “1”). The data that has become “1” is generated and supplied to the error correction unit 8.

The error correction unit 8 takes in the 272-bit (1-block code) data output from the control unit 7, and performs error correction processing on the data by using the (272,190) shortened difference set cyclic code. At the same time, the syndrome obtained at the time of this error correction is supplied to the syndrome check unit 9, and the data obtained by the error correction processing is supplied to the changeover switch unit 10.

The syndrome check unit 9 takes in the syndrome output from the error correction unit 8 and determines whether the error correction is successful or not, and when the error correction is successful, generates a switch-on signal. This is supplied to the changeover switch unit 10, a value of "0" is generated as a syndrome check result, and this is supplied to the control unit 7. When error correction fails, a switch-off signal is generated and this is sent. The value is supplied to the changeover switch unit 10 and a value other than “0” is generated as a result of the syndrome check and is supplied to the control unit 7.

The change-over switch unit 10 takes in the error-corrected data output from the error correction unit 8 when the switch-on signal is output from the syndrome check unit 9, and the next-stage circuit (not shown). Supply to
Further, when the switch-off signal is output from the syndrome check unit 9, the acquisition of the error-corrected data output from the error correction unit 8 is interrupted so that erroneous data is not supplied to the next-stage circuit. Switch contacts.

Next, the results of comparison between the conventional example and this example are shown in FIGS.

Now, when the data interleaved with 48 bits is stored in the optical card with a storage length of 1 μm of 5 μm, the bit in one track of the optical card is “1” for the conventional method and the method according to this embodiment. When the ratio of 1 ”and the correctable burst length were calculated, all the data in the period in which the data was lost as in the past was“ 0 ”.
In such a case, the correctable burst length becomes shorter as the ratio of the bits in one track to “1” becomes higher, as shown in FIG. When all are set to "1", the ratio of the bits in one track to "1" is 50% as shown in FIG.
The correctable burst length up to the part is the same as the conventional one.
It has been found that the correctable burst length can be significantly lengthened in the portion of 0% or more.

As described above, in the present embodiment, the MFM-RZ encoding method is used as the encoding method and the (272,190) shortened difference set cyclic code is used as the error correcting code, and the data is already recorded. When this data is read, when this data is not lost, or when it is lost and all the data is set to "0", an error due to the (272,190) shortened difference set cyclic code is applied to this data. When the data is decoded by performing the error correction by the correction method and the data is lost and the data cannot be corrected even if all the data is set to "0", all the lost parts in the data are "1". Data is used, and the data is decoded by performing error correction on the data by the error correction method using the (272,190) shortened difference set cyclic code. , Even if the information recording medium is scratched and data is continuously lost, it is possible to prevent the error rate at the time of decoding from being lowered due to the contents of the original data, thereby significantly improving the error correction capability. be able to.

In the above-mentioned embodiment, the rising change portion at the center of the bit period is "1" and the other portions are "0", but this may be reversed. In this case, the same effect as that of the above-described embodiment can be obtained by setting the data in the data loss period to "0".

Further, as shown in FIG. 6, two systems of error correction functions are prepared, and when data loss is detected, all the data in the loss period are set to "0" (control section 7a and error correction section). 8a and a circuit including a syndrome check unit 9a) and a system (a circuit including a control unit 7b, an error correction unit 8b, and a syndrome check unit 9b) that is all "1". It is also possible to correct the error and select the result of which the syndrome is “0”.

[0033]

As described above, according to the present invention, even if the information recording medium is scratched or the like and data is continuously lost, the error rate at the time of decoding does not decrease due to the content of the original data. Therefore, the error correction capability can be significantly improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an error correction circuit according to the present invention.

FIG. 2 is an explanatory diagram showing a relationship between a ratio in which a bit in one track is “1” and a correctable burst length when a conventional method is applied.

FIG. 3 is an explanatory diagram showing the relationship between the ratio of bits in one track being “1” and the correctable burst length when the error correction method according to the present invention is applied.

FIG. 4 is a timing chart for explaining a conventionally used NRZ encoding method, MFM encoding method, and MFM-RZ encoding method.

FIG. 5 is a timing chart for explaining problems of the conventional method based on the NRZ encoding method, the MFM encoding method, and the MFM-RZ encoding method shown in FIG.

FIG. 6 is a block diagram showing another embodiment of the error correction circuit according to the present invention.

[Explanation of symbols]

1 error correction circuit 2 data reading unit 3 timing reproduction unit 4 data loss period detection unit 5 272 bit loss flag memory unit (alternative data generation unit) 6 272 bit data memory unit 7, 7a, 7b control unit 8, 8a, 8b error Correction unit 9, 9a, 9b Syndrome check unit 10 Changeover switch unit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location G11B 20/18 570 E 9074-5D C3-4 576 F 9074-5D C1-2 (72) Inventor Toru Kuroda 1-10-11 Kinuta, Setagaya-ku, Tokyo Inside the Broadcasting Technology Laboratory, Japan Broadcasting Corporation (72) Inventor Tsuna, Yamazaki 25 Oyama, Sakado, Saitama

Claims (4)

[Claims] 1. An error correction circuit for decoding data read from an information recording medium by a preset error correction method, wherein at least a part of the data read from the information recording medium is lost. , The data loss period detecting section for detecting this, and the replacement data in which all bits are “1” or “0” during the period when the data loss period detecting section detects the loss of data. An alternative data generation unit to generate, and among the data read from the information recording medium, after the data during the data loss period is switched to the data obtained by the alternative data generation unit, a preset error correction is performed. An error correction circuit comprising: an error correction unit that decodes by a method and generates corrected data. 2. An error correction circuit for decoding data read from an information recording medium by a preset error correction method, wherein at least a part of the data read from the information recording medium is lost. , The data loss period detecting section for detecting this, and the replacement data in which all bits are “1” or “0” during the period when the data loss period detecting section detects the loss of data. An alternative data generation unit for generating and decoding the data read from the information recording medium by a preset error correction method to generate corrected data, and when the error correction processing fails, the information Of the data read from the recording medium, the data during the data loss period is switched to the data obtained by the alternative data generation unit, and then a preset error correction is performed. An error correction circuit comprising: an error correction unit that decodes by a method and generates corrected data. 3. The error correction circuit according to claim 1, wherein the data read from the information recording medium is data encoded by the MFM-RZ system, and the error correction unit decodes the data by the MFM-RZ system. . 4. The data read from the information recording medium is data that is encoded by the MFM-RZ method and uses a (272,190) shortened difference set cyclic code as an error correction code, and the error correction unit is an MFM. -RZ method,
(272,190) The error correction circuit according to any one of claims 1, 2, and 3, wherein data is corrected by a shortened difference set cyclic code system.